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README.md

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 [![Go Report Card](https://goreportcard.com/badge/github.com/cpmech/gosl)](https://goreportcard.com/report/github.com/cpmech/gosl)
 [![Awesome](https://cdn.rawgit.com/sindresorhus/awesome/d7305f38d29fed78fa85652e3a63e154dd8e8829/media/badge.svg)](https://github.com/avelino/awesome-go)
 
-Gosl is a set of tools for developing scientific simulations using the Go language. We mainly consider the development of numerical methods and solvers for differential equations but also present some functions for fast Fourier transforms, the generation of random numbers, probability distributions, and computational geometry.
+Gosl is a set of tools for developing scientific simulations using the Go language. We mainly consider the development of numerical methods and solvers for differential equations. We also present some functions for fast Fourier transforms, the generation of random numbers, probability distributions, and computational geometry.
 
-This library contains essential functions for linear algebra computations (operations between all combinations of vectors and matrices, eigenvalues and eigenvectors, linear solvers) and the development of numerical methods (e.g. numerical quadrature).
+This library contains essential functions for linear algebra computations (operations between all combinations of vectors and matrices, eigenvalues and eigenvectors, linear solvers) and the development of numerical methods (e.g., numerical quadrature).
 
-We link Gosl with existing libraries written in C and Fortran, such as OpenBLAS, LAPACK, UMFPACK, MUMPS, QUADPACK and FFTW3. These existing libraries have been fundamental for the development of high-performant simulations over many years. We believe that it is nearly impossible to rewrite these libraries in native Go and at the same time achieve the same speed delivered by them. Just for reference, a naive implementation of matrix-matrix multiplication in Go is more than 100 times slower than OpenBLAS.
+We link Gosl with existing libraries written in C and Fortran, such as OpenBLAS, LAPACK, UMFPACK, MUMPS, QUADPACK, and FFTW3. These libraries have been fundamental for the development of high-performant simulations over many years. We believe that it is nearly impossible to rewrite these libraries in native Go and achieve the same speed delivered by them. For reference, a naive implementation of matrix-matrix multiplication in Go is more than 100 times slower than OpenBLAS.
 
 ## Installation
 
-Because of the other libraries, the easiest way to work with Gosl is via Docker. Having Docker and VS Code installed, you can start developing powerful numerical simulations using Gosl in a matter of minutes. Furthermore, it works on Windows, Linux, and macOS out of the box.
+Because of the other libraries, Docker is the easiest way to work with Gosl. Having Docker and VS Code installed, you can start developing powerful numerical simulations using Gosl in a matter of minutes. Furthermore, it works out of the box on Windows, Linux, and MacOS.
 
 ### Containerized
 
@@ -59,27 +59,27 @@ Done. Installation completed.
 Gosl includes the following _essential_ packages:
 
 - [chk](https://github.com/cpmech/gosl/tree/master/chk). To check numerical results and for unit testing
-- [io](https://github.com/cpmech/gosl/tree/master/io). Input/output including printing to the terminal and handling files
-- [utl](https://github.com/cpmech/gosl/tree/master/utl). To generate series (e.g. linspace) and other functions as in pylab/matlab/octave
+- [io](https://github.com/cpmech/gosl/tree/master/io). Input/output, including printing to the terminal and handling files
+- [utl](https://github.com/cpmech/gosl/tree/master/utl). To generate series (e.g., linspace) and other functions as in pylab/matlab/octave
 - [la](https://github.com/cpmech/gosl/tree/master/la). Linear Algebra: vector, matrix, efficient sparse solvers, eigenvalues, decompositions
 
 Gosl includes the following _main_ packages:
 
 - [fun](https://github.com/cpmech/gosl/tree/master/fun). Special functions, DFT, FFT, Bessel, elliptical integrals, orthogonal polynomials, interpolators
 - [gm](https://github.com/cpmech/gosl/tree/master/gm). Geometry algorithms and structures
 - [hb](https://github.com/cpmech/gosl/tree/master/hb). Pseudo hierarchical binary (hb) data file format
-- [num](https://github.com/cpmech/gosl/tree/master/num). Fundamental numerical methods such as root solvers, non-linear solvers, numerical derivatives and quadrature
+- [num](https://github.com/cpmech/gosl/tree/master/num). Fundamental numerical methods such as root solvers, non-linear solvers, numerical derivatives, and quadrature
 - [ode](https://github.com/cpmech/gosl/tree/master/ode). Solvers for ordinary differential equations
 - [opt](https://github.com/cpmech/gosl/tree/master/opt). Numerical optimization: Interior Point, Conjugate Gradients, Powell, Grad Descent
 - [pde](https://github.com/cpmech/gosl/tree/master/pde). Solvers for partial differential equations (FDM, Spectral, FEM)
 - [rnd](https://github.com/cpmech/gosl/tree/master/rnd). Random numbers and probability distributions
 
 (see each subdirectory for more information)
 
-For the sake of maintenance (see next section), we have removed the previous `mpi` sub-package. However, we recommend the external library [gompi](https://github.com/sbromberger/gompi) if you plan to use MPI.
+We have removed the previous `mpi` sub-package for maintenance (see next section). However, if you plan to use MPI, we recommend the external library [gompi](https://github.com/sbromberger/gompi).
 
 ## Previous version
 
 The previous version, including more packages, is [available here ](https://github.com/cpmech/gosl/tree/stable-1.1.3) and can be used with the Docker image 1.1.3 as in this [hello gosl example](https://github.com/cpmech/hello-gosl-old-1.1.3).
 
-These other packages, such as machine learning, plotting, etc., have been removed because they do not depend on CGO and may be developed independently. We can now maintain the core of Gosl more efficiently, which has a focus on the foundation for other scientific code.
+These other packages, such as machine learning, plotting, etc., have been removed because they do not depend on CGO and may be developed independently. We can now more efficiently maintain the core of Gosl, which focuses on the foundation for other scientific codes.